#define FUNC_READ 1
#define FUNC_WRITE 1
/**********************************************************/
/* Optiboot bootloader for Arduino                        */
/*                                                        */
/* http://optiboot.googlecode.com                         */
/*                                                        */
/* Arduino-maintained version : See README.TXT            */
/* http://code.google.com/p/arduino/                      */
/*  It is the intent that changes not relevant to the     */
/*  Arduino production environment get moved from the      */
/*  optiboot project to the arduino project in "lumps."   */
/*                                                        */
/* Heavily optimised bootloader that is faster and        */
/* smaller than the Arduino standard bootloader           */
/*                                                        */
/* Enhancements:                                          */
/*   Fits in 512 bytes, saving 1.5K of code space         */
/*   Higher baud rate speeds up programming               */
/*   Written almost entirely in C                         */
/*   Customisable timeout with accurate timeconstant      */
/*   Optional virtual UART. No hardware UART required.    */
/*   Optional virtual boot partition for devices without. */
/*                                                        */
/* What you lose:                                         */
/*   Implements a skeleton STK500 protocol which is       */
/*     missing several features including EEPROM          */
/*     programming and non-page-aligned writes            */
/*   High baud rate breaks compatibility with standard    */
/*     Arduino flash settings                             */
/*                                                        */
/* Fully supported:                                       */
/*   ATmega168 based devices  (Diecimila etc)             */
/*   ATmega328P based devices (Duemilanove etc)           */
/*                                                        */
/* Beta test (believed working.)                          */
/*   ATmega8 based devices (Arduino legacy)               */
/*   ATmega328 non-picopower devices                      */
/*   ATmega644P based devices (Sanguino)                  */
/*   ATmega1284P based devices                            */
/*   ATmega1280 based devices (Arduino Mega)              */
/*   ATmega2560 based devices (Arduino Mega)              */
/*                                                        */
/* Alpha test                                             */
/*   ATmega32                                             */
/*                                                        */
/* Does not support:                                      */
/*   USB based devices (eg. Teensy, Leonardo)             */
/*                                                        */
/* Assumptions:                                           */
/*   The code makes several assumptions that reduce the   */
/*   code size. They are all true after a hardware reset, */
/*   but may not be true if the bootloader is called by   */
/*   other means or on other hardware.                    */
/*     No interrupts can occur                            */
/*     UART and Timer 1 are set to their reset state      */
/*     SP points to RAMEND                                */
/*                                                        */
/* Code builds on code, libraries and optimisations from: */
/*   stk500boot.c          by Jason P. Kyle               */
/*   Arduino bootloader    http://arduino.cc              */
/*   Spiff's 1K bootloader http://spiffie.org/know/arduino_1k_bootloader/bootloader.shtml */
/*   avr-libc project      http://nongnu.org/avr-libc     */
/*   Adaboot               http://www.ladyada.net/library/arduino/bootloader.html */
/*   AVR305                Atmel Application Note         */
/*                                                        */
/*                                                        */
/* Copyright 2013-2015 by Bill Westfield.                 */
/* Copyright 2010 by Peter Knight.                        */
/*                                                        */
/* This program is free software; you can redistribute it */
/* and/or modify it under the terms of the GNU General    */
/* Public License as published by the Free Software       */
/* Foundation; either version 2 of the License, or        */
/* (at your option) any later version.                    */
/*                                                        */
/* This program is distributed in the hope that it will   */
/* be useful, but WITHOUT ANY WARRANTY; without even the  */
/* implied warranty of MERCHANTABILITY or FITNESS FOR A   */
/* PARTICULAR PURPOSE.  See the GNU General Public        */
/* License for more details.                              */
/*                                                        */
/* You should have received a copy of the GNU General     */
/* Public License along with this program; if not, write  */
/* to the Free Software Foundation, Inc.,                 */
/* 59 Temple Place, Suite 330, Boston, MA  02111-1307 USA */
/*                                                        */
/* Licence can be viewed at                               */
/* http://www.fsf.org/licenses/gpl.txt                    */
/*                                                        */
/**********************************************************/


/**********************************************************/
/*                                                        */
/* Optional defines:                                      */
/*                                                        */
/**********************************************************/
/*                                                        */
/* BIGBOOT:                                              */
/* Build a 1k bootloader, not 512 bytes. This turns on    */
/* extra functionality.                                   */
/*                                                        */
/* BAUD_RATE:                                             */
/* Set bootloader baud rate.                              */
/*                                                        */
/* SOFT_UART:                                             */
/* Use AVR305 soft-UART instead of hardware UART.         */
/*                                                        */
/* LED_START_FLASHES:                                     */
/* Number of LED flashes on boot-up.                       */
/*                                                        */
/* LED_DATA_FLASH:                                        */
/* Flash LED when transferring data. For boards without   */
/* TX or RX LEDs, or for people who like blinky lights.   */
/*                                                        */
/* SUPPORT_EEPROM:                                        */
/* Support reading and writing from EEPROM. This is not   */
/* used by Arduino, so off by default.                    */
/*                                                        */
/* TIMEOUT_MS:                                            */
/* Bootloader timeout period, in milliseconds.            */
/* 500,1000,2000,4000,8000 supported.                     */
/*                                                        */
/* UART:                                                  */
/* UART number (0..n) for devices with more than          */
/* one hardware uart (644P, 1284P, etc)                   */
/*                                                        */
/* RS485:                                                 */
/* Either a pin (ex: "B5") or a pin followed by _INV      */
/* (ex: "B5_INV") which indicates inverted polarity.      */
/* This pin will be held low while transmitting in order  */
/* to control the direction pin of an RS485 tranciever    */
/*                                                        */
/* NO_START_APP_ON_POR:                                   */
/* If NO_START_APP_ON_POR is set, the bootloader will     */
/* also run on power-on                                   */
/*                                                        */
/* START_APP_ON_EXTR:                                     */
/* If START_APP_ON_EXTR is set, the bootloader will not   */
/* run in the event of an external reset.                 */
/*                                                        */
/* If both are set, the bootloader will only run if the   */
/* app jumps directly to it.                              */
/*                                                        */
/* Regardless of what method you use (even neither, ie    */
/* you have it run on external reset only, if you do a    */
/* watchdog reset from within the app, and the flag that  */
/* is associated with a reset cause that would enter the  */
/* is set in MCUSR, because you didn't ever reset it the  */
/* bootloader will assume that it ran and timed out via   */
/* watchdog reset and reset WDRF before starting the app  */
/*                                                        */
/* TIMEOUT                                                */
/* Specify how long to wait for an upload before jumping  */
/* to the app. Default is 1 (second). Valid options are   */
/* 1, 2, 4, and 8, as well as 5 and 25 which will run for */
/* 500ms or 250ms and 125ms respectively.                 */
/* As the timeout gets shorter, it becomes harder to time */
/* the start of upload correctly to communicate with the  */
/* bootloader. Shorter timeouts are not viable.           */
/*                                                        */
/**********************************************************/

/**********************************************************/
/* Version Numbers!                                       */
/*                                                        */
/* Arduino Optiboot now includes this Version number in   */
/* the source and object code.                            */
/*                                                        */
/* Version 3 was released as zip from the optiboot        */
/*  repository and was distributed with Arduino 0022.     */
/* Version 4 starts with the arduino repository commit    */
/*  that brought the arduino repository up-to-date with   */
/*  the optiboot source tree changes since v3.            */
/* Version 5 was created at the time of the new Makefile  */
/*  structure (Mar, 2013), even though no binaries changed*/
/* Version 6 added EEPROM support, including causing an   */
/*  error when trying to write eeprom with versions that  */
/*  didn't have the code there. Makefiles were further    */
/*  restructured.  Overlapping SPM/download removed.      */
/* Version 7 straightened out the MCUSR and RESET         */
/*  handling, did MORE Makefile mods.  EEPROM support now */
/*  fits in 512 bytes, if you turn off LED Blinking.      */
/*  Various bigboot and virboot targets were fixed.       */
/* Version 8.0 adds the do_spm code callable from Apps.   */
/*                                                        */
/* It would be good if versions implemented outside the   */
/*  official repository used an out-of-seqeunce version   */
/*  number (like 104.6 if based on based on 4.5) to       */
/*  prevent collisions.  The CUSTOM_VERSION=n option      */
/*  adds n to the high version to facilitate this.        */
/*                                                        */
/**********************************************************/

/**********************************************************/
/* Edit History:                                          */
/*                                                        */
/* Feb 2022 Spence Konde for ATTinyCore                   */
/*           github.com/SpenceKonde                       */
/* 58.1 Add support for REMAP=1 on t841, 441              */
/*      Add support for TXPIN, RXPIN, and while I'm at it */
/*      general specification of the PORT too.            */
/*      No checking is performed that the registers given */
/*      for soft uart are on the same port.               */
/*      Remove default software serial pins for parts with*/
/*      hardware serial. Error if software serial is      */
/*      requested but all parameters not provided.        */
/*      Parts that do have a default need only specify the*/
/*      TX and RX bits as TXPIN and RXPIN.                */
/*      Remove conditional compilation for megaAVR parts  */
/*      There are already enough unholy things done to this*/
/*      version that it shouldn't compile for any ATmega  */
/*      so why imply that it would?                       */
/*      Adjust most indentation to match all of my cores  */
/* 58.0 Pull in RS485 support by Vladimir Dronnikov       */
/*      ( github.com/dvv ) as used in                     */
/*      github.com/SodaqMoja/optiboot                     */
/*      Add support for active high RS485 TX hardware,    */
/*      which apparently exists (?!)                      */
/*      Add support for options to control behavior based */
/*      on the reset cause flags                          */
/*                                                        */
/* Sep 2018                                               */
/* 8.0  WestfW (and Majekw and MCUDude)                   */
/*      Include do_spm routine callable from the app      */
/*      at BOOTSTART+2, controllable with compile option  */
/* July 2018                                              */
/* 7.0    WestfW (with much input from Others)            */
/*    Fix MCUSR treatment as per much discussion,         */
/*     Patches by MarkG55, majekw.  Preserve value        */
/*     for the application, as much as possible.          */
/*     see https://github.com/Optiboot/optiboot/issues/97 */
/*    Optimize a bit by implementing a union for the      */
/*     various 16bit address values used (based on        */
/*     observation by "aweatherguy", but different.)      */
/*    Slightly optimize math in VIRTUAL_BOOT code         */
/*    Add some virboot targets, fix some fuses.           */
/*    Implement LED_START_ON; less code than flashes      */
/* Aug 2014                                               */
/* 6.2 WestfW: make size of length variables dependent    */
/*              on the SPM_PAGESIZE.  This saves space    */
/*              on the chips where it's most important.   */
/* 6.1 WestfW: Fix OPTIBOOT_CUSTOMVER (send it!)          */
/*             Make no-wait mod less picky about          */
/*               skipping the bootloader.                 */
/*             Remove some dead code                      */
/* Jun 2014                                               */
/* 6.0 WestfW: Modularize memory read/write functions     */
/*             Remove serial/flash overlap                */
/*              (and all references to NRWWSTART/etc)     */
/*             Correctly handle pagesize > 255bytes       */
/*             Add EEPROM support in BIGBOOT (1284)       */
/*             EEPROM write on small chips now causes err */
/*             Split Makefile into smaller pieces         */
/*             Add Wicked devices Wildfire                */
/*           Move UART=n conditionals into pin_defs.h     */
/*           Remove LUDICOUS_SPEED option                 */
/*           Replace inline assembler for .version        */
/*              and add OPTIBOOT_CUSTOMVER for user code  */
/*             Fix LED value for Bobuino (Makefile)       */
/*             Make all functions explicitly inline or    */
/*              noinline, so we fit when using gcc4.8     */
/*             Change optimization options for gcc4.8     */
/*             Make ENV=arduino work in 1.5.x trees.      */
/* May 2014                                               */
/* 5.0 WestfW: Add support for 1Mbps UART                 */
/* Mar 2013                                               */
/* 5.0 WestfW: Major Makefile restructuring.              */
/*             See Makefile and pin_defs.h                */
/*             (no binary changes)                        */
/*                                                        */
/* 4.6 WestfW/Pito: Add ATmega32 support                  */
/* 4.6 WestfW/radoni: Don't set LED_PIN as an output if   */
/*                    not used. (LED_START_FLASHES = 0)   */
/* Jan 2013                                               */
/* 4.6 WestfW/dkinzer: use autoincrement lpm for read     */
/* 4.6 WestfW/dkinzer: pass reset cause to app in R2      */
/* Mar 2012                                               */
/* 4.5 WestfW: add infrastructure for non-zero UARTS.     */
/* 4.5 WestfW: fix SIGNATURE_2 for m644 (bad in avr-libc) */
/* Jan 2012:                                              */
/* 4.5 WestfW: fix NRWW value for m1284.                  */
/* 4.4 WestfW: use attribute OS_main instead of naked for */
/*             main().  This allows optimizations that we */
/*             count on, which are prohibited in naked    */
/*             functions due to PR42240.  (keeps us less  */
/*             than 512 bytes when compiler is gcc4.5     */
/*             (code from 4.3.2 remains the same.)        */
/* 4.4 WestfW and Maniacbug:  Add m1284 support.  This    */
/*             does not change the 328 binary, so the     */
/*             version number didn't change either. (?)   */
/* June 2011:                                             */
/* 4.4 WestfW: remove automatic soft_uart detect (didn't  */
/*             know what it was doing or why.)  Added a   */
/*             check of the calculated BRG value instead. */
/*             Version stays 4.4; existing binaries are   */
/*             not changed.                               */
/* 4.4 WestfW: add initialization of address to keep      */
/*             the compiler happy.  Change SC'ed targets. */
/*             Return the SW version via READ PARAM       */
/* 4.3 WestfW: catch framing errors in getch(), so that   */
/*             AVRISP works without HW kludges.           */
/*  http://code.google.com/p/arduino/issues/detail?id=368n*/
/* 4.2 WestfW: reduce code size, fix timeouts, change     */
/*             verifySpace to use WDT instead of appstart */
/* 4.1 WestfW: put version number in binary.          */
/**********************************************************/

#define OPTIBOOT_MAJVER 8
#define OPTIBOOT_MINVER 0

/*
 * OPTIBOOT_CUSTOMVER should be defined (by the makefile) for custom edits
 * of optiboot.  That way you don't wind up with very different code that
 * matches the version number of a "released" optiboot.
 */

#if !defined(OPTIBOOT_CUSTOMVER)
#define OPTIBOOT_CUSTOMVER 51
#endif

unsigned const int __attribute__((section(".version")))
optiboot_version = 256*(OPTIBOOT_MAJVER + OPTIBOOT_CUSTOMVER) + OPTIBOOT_MINVER;


#include <inttypes.h>
#include <avr/io.h>
#include <avr/pgmspace.h>
#include <avr/eeprom.h>

/*
 * optiboot uses several "address" variables that are sometimes byte pointers,
 * sometimes word pointers. sometimes 16bit quantities, and sometimes built
 * up from 8bit input characters.  avr-gcc is not great at optimizing the
 * assembly of larger words from bytes, but we can use the usual union to
 * do this manually.  Expanding it a little, we can also get rid of casts.
 */
typedef union {
    uint8_t  *bptr;
    uint16_t *wptr;
    uint16_t word;
    uint8_t bytes[2];
} addr16_t;

/*
 * Note that we use a replacement of "boot.h"
 * <avr/boot.h> uses sts instructions, but this version uses out instructions
 * This saves cycles and program memory, if possible.
 * boot_opt.h pulls in the standard boot.h for the odd target (?)
 */
#include "boot_opt.h"


// We don't use <avr/wdt.h> as those routines have interrupt overhead we don't need.

/*
 * pin_defs.h
 * This contains most of the rather ugly defines that implement our
 * ability to use UART=n and LED=D3, and some avr family bit name differences.
 */
#include "pin_defs.h"

/*
 * stk500.h contains the constant definitions for the stk500v1 comm protocol
 */
#include "stk500.h"

#ifndef LED_START_FLASHES
#define LED_START_FLASHES 0
#endif

/* set the UART baud rate defaults */
#ifndef BAUD_RATE
  #if F_CPU >= 8000000L
    // This is a shitty default, because it has 2% error. In the same direction
    // that the 841 and 1634's clocks skew at VCC > 4.0V.
    // 76800 is dead-on and a better choice
    #define BAUD_RATE   115200L // Highest rate Avrdude win32 will support
  #elif F_CPU >= 1000000L
    #define BAUD_RATE   9600L   // 19200 also supported, but with significant error
    // 19200 is a bad speed anyway because it matches (and uses same protocol as)
    // arduino as ISP, and the resulting behavior will flummox almost everyone.
  #elif F_CPU >= 128000L
    #define BAUD_RATE   4800L   // Good for 128kHz internal RC
  #else
    #define BAUD_RATE 1200L     // Good even at 32768Hz
  #endif
#endif

#ifndef UART
#define UART 0
#endif

#ifndef SOFT_UART
  #ifdef SINGLESPEED
    /* Single speed option */
    #define BAUD_SETTING (( (F_CPU + BAUD_RATE * 8L) / ((BAUD_RATE * 16L))) - 1 )
    #define BAUD_ACTUAL (F_CPU/(16 * ((BAUD_SETTING)+1)))
  #else
    /* Normal U2X usage */
    #define BAUD_SETTING (( (F_CPU + BAUD_RATE * 4L) / ((BAUD_RATE * 8L))) - 1 )
    #define BAUD_ACTUAL (F_CPU/(8 * ((BAUD_SETTING)+1)))
  #endif
  #if BAUD_ACTUAL <= BAUD_RATE
    #define BAUD_ERROR (( 100*(BAUD_RATE - BAUD_ACTUAL) ) / BAUD_RATE)
    #if BAUD_ERROR >= 5
      #error BAUD_RATE off by greater than -5%
    #elif BAUD_ERROR >= 2  && !defined(PRODUCTION)
      #warning BAUD_RATE off by greater than -2%
    #endif
  #else
    #define BAUD_ERROR (( 100*(BAUD_ACTUAL - BAUD_RATE) ) / BAUD_RATE)
    #if BAUD_ERROR >= 5
      #error BAUD_RATE off by greater than 5%
    #elif BAUD_ERROR >= 2  && !defined(PRODUCTION)
      #warning BAUD_RATE off by greater than 2%
    #endif
  #endif

  #if BAUD_SETTING > 255
      #error Unachievable baud rate (too slow) BAUD_RATE
  #endif // baud rate slow check
  #if (BAUD_SETTING - 1) < 3
    #if BAUD_ERROR != 0 // permit high bitrates (ie 1Mbps@16MHz) if error is zero
      #error Unachievable baud rate (too fast) BAUD_RATE
    #endif
  #endif // baud rate fast check
#endif // SOFT_UART

/* Watchdog settings */
#define WATCHDOG_OFF    (0)
#define WATCHDOG_16MS   (_BV(WDE))
#define WATCHDOG_32MS   (_BV(WDP0) | _BV(WDE))
#define WATCHDOG_64MS   (_BV(WDP1) | _BV(WDE))
#define WATCHDOG_125MS  (_BV(WDP1) | _BV(WDP0) | _BV(WDE))
#define WATCHDOG_250MS  (_BV(WDP2) | _BV(WDE))
#define WATCHDOG_500MS  (_BV(WDP2) | _BV(WDP0) | _BV(WDE))
#define WATCHDOG_1S     (_BV(WDP2) | _BV(WDP1) | _BV(WDE))
#define WATCHDOG_2S     (_BV(WDP2) | _BV(WDP1) | _BV(WDP0) | _BV(WDE))\
#define WATCHDOG_4S     (_BV(WDP3) | _BV(WDE))
#define WATCHDOG_8S     (_BV(WDP3) | _BV(WDP0) | _BV(WDE))

#ifdef TIMEOUT
  #if TIMEOUT==1
    #define WDTPERIOD WATCHDOG_1S
  #elif TIMEOUT==2
    #define WDTPERIOD WATCHDOG_2S
  #elif TIMEOUT==4
    #define WDTPERIOD WATCHDOG_4S
  #elif TIMEOUT==8
    #define WDTPERIOD WATCHDOG_8S
  #elif TIMEOUT==5 //half second
    #define WDTPERIOD WATCHDOG_500MS
  #elif TIMEOUT==25 //quarter second
    #define WDTPERIOD WATCHDOG_250MS
  #elif TIMEOUT==12 //eighth second
    #define WDTPERIOD WATCHDOG_125MS
  #else
    #error "TIMEOUT specified but invalid"
  #endif
#else
  #define WDTPERIOD WATCHDOG_1S
#endif

#define MCUSTATUSREG MCUSR


/*
 * We can never load flash with more than 1 page at a time, so we can save
 * some code space on parts with smaller pagesize by using a smaller int.
 */
#if SPM_PAGESIZE > 255
typedef uint16_t pagelen_t;
#define GETLENGTH(len) len = getch()<<8; len |= getch()
#else
typedef uint8_t pagelen_t;
#define GETLENGTH(len) (void) getch() /* skip high byte */; len = getch()
#endif


/* Function Prototypes
 * The main() function is in init9, which removes the interrupt vector table
 * we don't need. It is also 'OS_main', which means the compiler does not
 * generate any entry or exit code itself (but unlike 'naked', it doesn't
 * suppress some compile-time options we want.)
 */

void pre_main(void) __attribute__ ((naked)) __attribute__ ((section (".init8")));
int main(void) __attribute__ ((OS_main)) __attribute__ ((section (".init9"))) __attribute__((used));

void __attribute__((noinline)) __attribute__((leaf)) putch(char);
uint8_t __attribute__((noinline)) __attribute__((leaf)) getch(void) ;
void __attribute__((noinline)) verifySpace();
void __attribute__((noinline)) watchdogConfig(uint8_t x);

static void getNch(uint8_t);
#if LED_START_FLASHES > 0
  static inline void flash_led(uint8_t);
#endif
static inline void watchdogReset();
static inline void writebuffer(int8_t memtype, addr16_t mybuff,
                   addr16_t address, pagelen_t len);
static inline void read_mem(uint8_t memtype,
                addr16_t, pagelen_t len);

#ifdef SOFT_UART
  void uartDelay() __attribute__ ((naked));
#endif

/*
 * RAMSTART should be self-explanatory.  It's bigger on parts with a
 * lot of peripheral registers.  Let 0x100 be the default
 * Note that RAMSTART (for optiboot) need not be exactly at the start of RAM.
 */
#if !defined(RAMSTART)  // newer versions of gcc avr-libc define RAMSTART
  #define RAMSTART 0x100
  /* Snip: Removed compensation for megaAVRs that set this wrong */
#endif

/* C zero initialises all global variables. However, that requires */
/* These definitions are NOT zero initialised, but that doesn't matter */
/* This allows us to drop the zero init code, saving us memory */
static addr16_t buff = {(uint8_t *)(RAMSTART)};

/* Virtual boot partition support */
#ifdef VIRTUAL_BOOT_PARTITION
  #define rstVect0_sav (*(uint8_t*)(RAMSTART+SPM_PAGESIZE*2+4))
  #define rstVect1_sav (*(uint8_t*)(RAMSTART+SPM_PAGESIZE*2+5))
  #define saveVect0_sav (*(uint8_t*)(RAMSTART+SPM_PAGESIZE*2+6))
  #define saveVect1_sav (*(uint8_t*)(RAMSTART+SPM_PAGESIZE*2+7))
  // Vector to save original reset jump:
  //   SPM Ready is least probably used, so it's default
  //   if not, use old way WDT_vect_num,
  //   or simply set custom save_vect_num in Makefile using vector name
  //   or even raw number.
  #if !defined (save_vect_num)
    #if defined (SPM_RDY_vect_num)
      #define save_vect_num (SPM_RDY_vect_num)
    #elif defined (SPM_READY_vect_num)
      #define save_vect_num (SPM_READY_vect_num)
    #elif defined (EE_RDY_vect_num)
      #define save_vect_num (EE_RDY_vect_num)
    #elif defined (EE_READY_vect_num)
      #define save_vect_num (EE_READY_vect_num)
    #elif defined (WDT_vect_num)
      #define save_vect_num (WDT_vect_num)
    #else
      #error "Can't find SPM or WDT interrupt vector for this CPU"
    #endif
  #endif //save_vect_num
  // check if it's on the same page (code assumes that)

  #if FLASHEND > 8192
    // AVRs with more than 8k of flash have 4-byte vectors, and use jmp.
    //  We save only 16 bits of address, so devices with more than 128KB
    //  may behave wrong for upper part of address space.
    #define rstVect0 2
    #define rstVect1 3
    #define saveVect0 (save_vect_num*4+2)
    #define saveVect1 (save_vect_num*4+3)
    #define appstart_vec (save_vect_num*2)
  #else
    // AVRs with up to 8k of flash have 2-byte vectors, and use rjmp.

    #define rstVect0 0
    #define rstVect1 1
    #define saveVect0 (save_vect_num*2)
    #define saveVect1 (save_vect_num*2+1)
    #define appstart_vec (save_vect_num)
  #endif
#else
  #define appstart_vec (0)
#endif // VIRTUAL_BOOT_PARTITION


/* everything that needs to run VERY early */
void pre_main(void) {
  // Allow convenient way of calling do_spm function - jump table,
  //   so entry to this function will always be here, independent of compilation,
  //   features etc
  asm volatile (
    "    rjmp    1f\n"
#ifndef APP_NOSPM
    "    rjmp    do_spm\n"
#else
    "   ret\n"   // if do_spm isn't include, return without doing anything
#endif
    "1:\n"
  );
}


/* main program starts here */
int main(void) {
  uint8_t ch;

  /*
   * Making these local and in registers prevents the need for initializing
   * them, and also saves space because code no longer stores to memory.
   * (initializing address keeps the compiler happy, but isn't really
   *  necessary, and uses 4 bytes of flash.)
   */
  register addr16_t address;
  register pagelen_t  length;

  // After the zero init loop, this is the first code to run.
  //
  // This code makes the following assumptions:
  //  No interrupts will execute
  //  SP points to RAMEND
  //  r1 contains zero
  //
  // If not, uncomment the following instructions:
  // cli();
  asm volatile ("clr __zero_reg__");

  /*
   * Protect as much from MCUSR as possible for application
   * and still skip bootloader if not necessary
   *
   * Code by MarkG55
   * see discussion in https://github.com/Optiboot/optiboot/issues/97
   */

  ch = MCUSTATUSREG;

  // Skip all logic and run bootloader if MCUSR is cleared (application request)
  if (ch != 0) {
    /*
     * To run the boot loader, External Reset Flag must be set.
     * If not, we could make shortcut and jump directly to application code.
     * Also WDRF set with EXTRF is a result of Optiboot timeout, so we
     * shouldn't run bootloader in loop :-) That's why:
     *  1. application is running if WDRF is cleared
     *  2. we clear WDRF if it's set with EXTRF to avoid loops
     * One problematic scenario: broken application code sets watchdog timer
     * without clearing MCUSR before and triggers it quickly. But it's
     * recoverable by power-on with pushed reset button.
     *
     * If NO_START_APP_ON_POR is defined, run bootloader after POR.
     * This allows use with reset disabled: power on and immediately
     * program.
     *
     * If START_APP_ON_EXTR is defined, don't run bootloader after
     * an external reset - only useful in combination with above,
     * for some unusual use cases.
     *
     */
#if (!(defined(START_APP_ON_EXTR)||defined(NO_START_APP_ON_POR))) //normal behavior
    if ((ch & (_BV(WDRF) | _BV(EXTRF))) != _BV(EXTRF)) {                      // Run app if EXTRF not set, or WDRF and EXTRF set
      if (ch & _BV(EXTRF)) {                                                  // Both WDRF and EXTRF are set
        /*
         * Clear WDRF because it was most probably set by wdr in bootloader.
         * It's also needed to avoid loop by broken application which could
         * prevent entering bootloader.
         * '&= allows CBI to be used, saves flash
         */
        MCUSTATUSREG &= ~(_BV(WDRF));
      }
#elif (defined(START_APP_ON_EXTR)&&defined(NO_START_APP_ON_POR))
    if ((ch & (_BV(PORF) | _BV(WDRF) | _BV(EXTRF))) != _BV(PORF)) {              // Run app unless only PORF is set
      if ((ch & (_BV(PORF) | _BV(WDRF)))==(_BV(PORF) | _BV(WDRF))) {              // If PORF and WDRF are set, could be from us, so reset WDRF.
        /*
         * Clear WDRF because it was most probably set by wdr in bootloader.
         * It's also needed to avoid loop by broken application which could
         * prevent entering bootloader.
         * '&= allows CBI to be used, saves flash
         */
        MCUSTATUSREG &= ~(_BV(WDRF));
      }
#elif ((!defined(START_APP_ON_EXTR))&&defined(NO_START_APP_ON_POR))
    if (ch & _BV(WDRF) )  {                                                     // WDRF is set, go to app
      if (ch & (_BV(PORF) | _BV(EXTRF))) {                                      // Unless ONLY WDRF is set, it could be from us, so reset WDRF
        /*
         * Clear WDRF because it was most probably set by wdr in bootloader.
         * It's also needed to avoid loop by broken application which could
         * prevent entering bootloader.
         * '&= allows CBI to be used, saves flash
         */
        MCUSTATUSREG &= ~(_BV(WDRF));
      }
#else // START_APP_ON_EXTR but neither  NO_START_APP_ON_WDR and NO_START_APP_ON_POR
  #warning "Bootloader can only start via app request because "
  #warning "START_APP_ON_EXTR is defined and NO_START_APP_ON_POR isn't"
    if (1) { //makes the braces line up - always start the app
#endif
      /*
       * save the reset flags in the designated register
       * This can be saved in a main program by putting code in .init0 (which
       * executes before normal c init code) to save R2 to a global variable.
       */
      __asm__ __volatile__ ("mov r2, %0\n" :: "r" (ch));

      // switch off watchdog
      watchdogConfig(WATCHDOG_OFF);
      // Note that appstart_vec is defined so that this works with either
      // real or virtual boot partitions.
       __asm__ __volatile__ (
        // Jump to 'save' or RST vector
#ifdef VIRTUAL_BOOT_PARTITION
        // full code version for virtual boot partition
        "ldi r30,%[rstvec]\n"
        "clr r31\n"
        "ijmp\n"::[rstvec] "M"(appstart_vec)
#else
#ifdef RAMPZ
        // use absolute jump for devices with lot of flash
        "jmp 0\n"::
#else
        // use rjmp to go around end of flash to address 0
        // it uses fact that optiboot_version constant is 2 bytes before end of flash
        "rjmp optiboot_version+2\n"
#endif //RAMPZ
#endif //VIRTUAL_BOOT_PARTITION
      );
    }
  } //end handling of MCUSR !=0
#ifdef LOWERCAL
  // If we need to bump down OSCCAL0 (for 841, 441, 828, 1634):
  OSCCAL0 = boot_signature_byte_get_short(1)-LOWERCAL;
#endif
#ifdef PRESCALE
  #ifdef CCP
    CCP=0xD8; //enable change of protected register
  #else
    CLKPR=1<<CLKPCE; //enable change of protected register
  #endif
  CLKPR=PRESCALE;
#endif
#if LED_START_FLASHES > 0
  // Set up Timer 1 for timeout counter
  #if defined(__AVR_ATtiny261__)||defined(__AVR_ATtiny461__)||defined(__AVR_ATtiny861__)
    TCCR1B = 0x0E; //div 8192 - we could divide by less since it's a 10-bit counter, but why?
  #elif defined(__AVR_ATtiny25__)||defined(__AVR_ATtiny45__)||defined(__AVR_ATtiny85__)
    TCCR1 = 0x0E; //div 8192 - it's an 8-bit timer.
  #elif defined(__AVR_ATtiny43__)
    #error "LED flash for Tiny43 not yet supported"
  #else
    TCCR1B = _BV(CS12) | _BV(CS10); // div 1024
  #endif
#endif


#ifndef SOFT_UART
  #ifdef LIN_UART
  //DDRB|=3;
    LINCR = (1 << LSWRES);
    //LINBRRL = (((F_CPU * 10L / 32L / BAUD_RATE) + 5L) / 10L) - 1;
    LINBRRL=(uint8_t)BAUD_SETTING;
    LINBTR = (1 << LDISR) | (8 << LBT0);
    LINCR = _BV(LENA) | _BV(LCMD2) | _BV(LCMD1) | _BV(LCMD0);
    LINDAT=0;
  #else
    #ifndef SINGLESPEED
      UART_SRA = _BV(U2X0); //Double speed mode USART0
    #endif
    #if defined(REMAP_UART) && defined(REMAP)
      REMAP = REMAP_UART;
    #elif defined(REMAP_UART)
      #error "REMAP_UART defined, but this part cannot remap it's UART!"
    #endif
    UART_SRB = _BV(RXEN0) | _BV(TXEN0);
    UART_SRC = _BV(UCSZ00) | _BV(UCSZ01);
    UART_SRL = (uint8_t)BAUD_SETTING;
  #endif // LIN_UART
#endif // soft_uart

#ifdef RS485
  RS485_DDR |= _BV(RS485);
  #ifdef RS485_INVERT
  RS485_PORT |= _BV(RS485);
  #else
  RS485_PORT &= ~_BV(RS485);
  #endif
#endif

  // Set up watchdog to trigger after 1s
  watchdogConfig(WDTPERIOD);

#if (LED_START_FLASHES > 0) || defined(LED_DATA_FLASH) || defined(LED_START_ON)
  /* Set LED pin as output */
  LED_DDR |= _BV(LED);
#endif

#ifdef SOFT_UART
  /* Set TX pin as output */
  UART_DDR |= _BV(UART_TX_BIT);
#endif

#if LED_START_FLASHES > 0
  /* Flash onboard LED to signal entering of bootloader */
  flash_led(LED_START_FLASHES * 2);
#else
#if defined(LED_START_ON)
  /* Turn on LED to indicate starting bootloader (less code!) */
  LED_PORT |= _BV(LED);
#endif
#endif

  /* Forever loop: exits by causing WDT reset */
  for (;;) {
    /* get character from UART */
    ch = getch();

    if(ch == STK_GET_PARAMETER) {
      unsigned char which = getch();
      verifySpace();
      /*
       * Send optiboot version as "SW version"
       * Note that the references to memory are optimized away.
       */
      if (which == STK_SW_MINOR) {
      putch(optiboot_version & 0xFF);
      } else if (which == STK_SW_MAJOR) {
      putch(optiboot_version >> 8);
      } else {
    /*
     * GET PARAMETER returns a generic 0x03 reply for
         * other parameters - enough to keep Avrdude happy
     */
    putch(0x03);
      }
    }
    else if(ch == STK_SET_DEVICE) {
      // SET DEVICE is ignored
      getNch(20);
    }
    else if(ch == STK_SET_DEVICE_EXT) {
      // SET DEVICE EXT is ignored
      getNch(5);
    }
    else if(ch == STK_LOAD_ADDRESS) {
      // LOAD ADDRESS
      address.bytes[0] = getch();
      address.bytes[1] = getch();
    #ifdef RAMPZ
      // Transfer top bit to LSB in RAMPZ
      if (address.bytes[1] & 0x80) {
        RAMPZ |= 0x01;
      }
      else {
        RAMPZ &= 0xFE;
      }
    #endif
      address.word *= 2; // Convert from word address to byte address
      verifySpace();
    }
    else if(ch == STK_UNIVERSAL) {
      #ifdef RAMPZ
      // LOAD_EXTENDED_ADDRESS is needed in STK_UNIVERSAL for addressing more than 128kB
        if (AVR_OP_LOAD_EXT_ADDR == getch()) {
          // get address
          getch();  // get '0'
          RAMPZ = (RAMPZ & 0x01) | ((getch() << 1) & 0xff);  // get address and put it in RAMPZ
          getNch(1); // get last '0'
          // response
          putch(0x00);
        } else {
          // everything else is ignored
          getNch(3);
          putch(0x00);
        }
      #else
        // UNIVERSAL command is ignored
        getNch(4);
        putch(0x00);
      #endif
    }
    /* Write memory, length is big endian and is in bytes */
    else if(ch == STK_PROG_PAGE) {
      // PROGRAM PAGE - we support flash programming only, not EEPROM
      uint8_t desttype;
      uint8_t *bufPtr;
      pagelen_t savelength;

      GETLENGTH(length);
      savelength = length;
      desttype = getch();

      // read a page worth of contents
      bufPtr = buff.bptr;
      do *bufPtr++ = getch();
      while (--length);

      // Read command terminator, start reply
      verifySpace();

#ifdef VIRTUAL_BOOT_PARTITION
  #if FLASHEND > 8192
    /*
     * AVR with 4-byte ISR Vectors and "jmp"
     * WARNING: this works only up to 128KB flash!
     */
    #if FLASHEND > (128*1024)
      #error "Can't use VIRTUAL_BOOT_PARTITION with more than 128k of Flash"
    #endif
      if (address.word == 0) {
        // This is the reset vector page. We need to live-patch the
        // code so the bootloader runs first.
        //
        // Save jmp targets (for "Verify")
        rstVect0_sav = buff.bptr[rstVect0];
        rstVect1_sav = buff.bptr[rstVect1];


        // Add jump to bootloader at RESET vector
        // WARNING: this works as long as 'main' is in first section
        buff.bptr[rstVect0] = ((uint16_t)main) & 0xFF;
        buff.bptr[rstVect1] = ((uint16_t)main) >> 8;
    #if (save_vect_num>SPM_PAGESIZE/4)
      } else if (address.word == (SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/4)))) { //allow for any vector
          saveVect0_sav = buff.bptr[saveVect0-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/4)))];
          saveVect1_sav = buff.bptr[saveVect1-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/4)))];

          // Move RESET jmp target to 'save' vector
          buff.bptr[saveVect0-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/4)))] = rstVect0_sav;
          buff.bptr[saveVect1-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/4)))] = rstVect1_sav;
      }
    #else
        saveVect0_sav = buff.bptr[saveVect0];
        saveVect1_sav = buff.bptr[saveVect1];

        // Move RESET jmp target to 'save' vector
        buff.bptr[saveVect0] = rstVect0_sav;
        buff.bptr[saveVect1] = rstVect1_sav;
      }
    #endif
  #else
  /*
   * AVR with 2-byte ISR Vectors and rjmp
   */
    if (address.word == rstVect0) {
      // This is the reset vector page. We need to live-patch
      // the code so the bootloader runs first.
      //
      // Move RESET vector to 'save' vector
      // Save jmp targets (for "Verify")
      rstVect0_sav = buff.bptr[rstVect0];
      rstVect1_sav = buff.bptr[rstVect1];
      addr16_t vect;
      vect.word = ((uint16_t)main);
      buff.bptr[0] = vect.bytes[0]; // rjmp to start of bootloader
      buff.bptr[1] = vect.bytes[1] | 0xC0;  // make an "rjmp"
    #if (save_vect_num > SPM_PAGESIZE/2)
        } else if (address.word == (SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/2)))) { //allow for any vector
          // Instruction is a relative jump (rjmp), so recalculate.
          // an RJMP instruction is 0b1100xxxx xxxxxxxx, so we should be able to
          // do math on the offsets without masking it off first.
          addr16_t vect;
          vect.bytes[0] = rstVect0_sav;
          vect.bytes[1] = rstVect1_sav;
          saveVect0_sav = buff.bptr[saveVect0-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/2)))];
          saveVect1_sav = buff.bptr[saveVect1-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/2)))];
          vect.word = (vect.word-save_vect_num); //subtract 'save' interrupt position
          // Move RESET jmp target to 'save' vector
          buff.bptr[saveVect0-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/2)))] = vect.bytes[0];
          buff.bptr[saveVect1-(SPM_PAGESIZE*(save_vect_num/(SPM_PAGESIZE/2)))] = (vect.bytes[1] & 0x0F)| 0xC0;  // make an "rjmp"
        }
    #else
        saveVect0_sav = buff.bptr[saveVect0];
        saveVect1_sav = buff.bptr[saveVect1];
        vect.bytes[0] = rstVect0_sav;
        vect.bytes[1] = rstVect1_sav;
        vect.word = (vect.word-save_vect_num); //subtract 'save' interrupt position
        // Move RESET jmp target to 'save' vector
        buff.bptr[saveVect0] = vect.bytes[0];
        buff.bptr[saveVect1] = (vect.bytes[1] & 0x0F)| 0xC0;  // make an "rjmp"
        // Add rjump to bootloader at RESET vector
        vect.word = ((uint16_t)main); // (main) is always <= 0x0FFF; no masking needed.
        buff.bptr[0] = vect.bytes[0]; // rjmp 0x1c00 instruction
      }
    #endif
  #endif // FLASHEND
#endif // VBP

      writebuffer(desttype, buff, address, savelength);


    }
    /* Read memory block mode, length is big endian.  */
    else if(ch == STK_READ_PAGE) {
      uint8_t desttype;
      GETLENGTH(length);

      desttype = getch();

      verifySpace();

      read_mem(desttype, address, length);
    }

    /* Get device signature bytes  */
    else if(ch == STK_READ_SIGN) {
      // READ SIGN - return what Avrdude wants to hear
      verifySpace();
      putch(SIGNATURE_0);
      putch(SIGNATURE_1);
      putch(SIGNATURE_2);
    }
    else if (ch == STK_LEAVE_PROGMODE) { /* 'Q' */
      // Adaboot no-wait mod
      watchdogConfig(WATCHDOG_16MS);
      verifySpace();
    }
    else {
      // This covers the response to commands like STK_ENTER_PROGMODE
      verifySpace();
    }
    putch(STK_OK);
  }
}

void putch(char ch) {
#ifndef SOFT_UART
  #ifndef LIN_UART
    #ifdef RS485
       uint8_t x;
      do {
        x = UART_SRA;
      } while (!(x & _BV(UDRE0)));
      // clear transmitted flag
      x |= _BV(TXC0);
      UART_SRA = x;
      // put transceiver to output mode
      #ifdef RS485_INVERT
      RS485_PORT &= ~_BV(RS485);
      #else
      RS485_PORT |= _BV(RS485);
      #endif
      // put char
      UART_UDR = ch;
      // wait for char transmitted
      while (!(UART_SRA & _BV(TXC0)));
      // put transceiver to input mode
      #ifdef RS485_INVERT
      RS485_PORT |= _BV(RS485);
      #else
      RS485_PORT &= ~_BV(RS485);
      #endif
    #else //not RS485
      while (!(UART_SRA & _BV(UDRE0))) {  /* Spin */ }
        UART_UDR = ch;
    #endif
  #else //is LIN UART
    while (!(LINSIR & _BV(LTXOK)))   {  /* Spin */ }
      UART_UDR = ch;
  #endif
#else

#ifdef RS485
  // put transceiver to output mode
  #ifdef RS485_INVERT
    RS485_PORT &= ~_BV(RS485);
  #else
    RS485_PORT |= _BV(RS485);
  #endif
#endif
  __asm__ __volatile__ (
    "   com %[ch]\n" // ones complement, carry set
    "   sec\n"
    "1: brcc 2f\n"
    "   cbi %[uartPort],%[uartBit]\n"
    "   rjmp 3f\n"
    "2: sbi %[uartPort],%[uartBit]\n"
    "   nop\n"
    "3: rcall uartDelay\n"
    "   rcall uartDelay\n"
    "   lsr %[ch]\n"
    "   dec %[bitcnt]\n"
    "   brne 1b\n"
    :
    :
      [bitcnt] "d" (10),
      [ch] "r" (ch),
      [uartPort] "I" (_SFR_IO_ADDR(UART_PORT)),
      [uartBit] "I" (UART_TX_BIT)
    :
      "r25"
  );

#ifdef RS485
  // put transceiver to input mode
  #ifdef RS485_INVERT
    RS485_PORT |= _BV(RS485);
  #else
    RS485_PORT &= ~_BV(RS485);
  #endif
#endif
#endif
}

uint8_t getch(void) {
  uint8_t ch;

  #ifdef LED_DATA_FLASH
    LED_PIN |= _BV(LED);
  #endif

  #ifdef SOFT_UART
      watchdogReset();
    __asm__ __volatile__ (
      "1: sbic  %[uartPin],%[uartBit]\n"  // Wait for start edge
      "   rjmp  1b\n"
      "   rcall uartDelay\n"          // Get to middle of start bit
      "2: rcall uartDelay\n"              // Wait 1 bit period
      "   rcall uartDelay\n"              // Wait 1 bit period
      "   clc\n"
      "   sbic  %[uartPin],%[uartBit]\n"
      "   sec\n"
      "   dec   %[bitCnt]\n"
      "   breq  3f\n"
      "   ror   %[ch]\n"
      "   rjmp  2b\n"
      "3:\n"
      :
        [ch] "=r" (ch)
      :
        [bitCnt] "d" (9),
        [uartPin] "I" (_SFR_IO_ADDR(UART_PIN)),
        [uartBit] "I" (UART_RX_BIT)
      :
        "r25"
  );
  #else
    #ifndef LIN_UART
      while(!(UART_SRA & _BV(RXC0)))  {  /* Spin */ }
      if (!(UART_SRA & _BV(FE0))) {
    #else
      while(!(LINSIR & _BV(LRXOK)))  {  /* Spin */ }
      if (!(LINSIR & _BV(LFERR))) {
    #endif
        /*
         * A Framing Error indicates (probably) that something is talking
         * to us at the wrong bit rate.  Assume that this is because it
         * expects to be talking to the application, and DON'T reset the
         * watchdog.  This should cause the bootloader to abort and run
         * the application "soon", if it keeps happening.  (Note that we
         * don't care that an invalid char is returned...)
         */
      watchdogReset();
    }

    ch = UART_UDR;
    #endif

  #ifdef LED_DATA_FLASH
    LED_PIN |= _BV(LED);
  #endif
  return ch;
}

#ifdef SOFT_UART
  // AVR305 equation: #define UART_B_VALUE (((F_CPU/BAUD_RATE)-23)/6)
  // Adding 3 to numerator simulates nearest rounding for more accurate baud rates
  #define UART_B_VALUE (((F_CPU/BAUD_RATE)-20)/6)
  #if UART_B_VALUE > 255
    #error Baud rate too slow for soft UART
  #endif

  #if UART_B_VALUE < 6
  // (this value is a "guess" at when loop/call overhead might become too
  //  significant for the soft uart to work.  It tests OK with the popular
  //  "ATtinycore" chips that need SOFT_UART, at the usual clock/baud combos.)
    #error Baud rate too high for soft UART
  #endif


  void uartDelay() {
    __asm__ __volatile__ (
      "ldi r25,%[count]\n"
      "1:dec r25\n"
      "brne 1b\n"
      "ret\n"
      ::[count] "M" (UART_B_VALUE)
    );
  }
#endif

void getNch(uint8_t count) {
  do getch(); while (--count);
  verifySpace();
}

void verifySpace() {
  if (getch() != CRC_EOP) {
    watchdogConfig(WATCHDOG_16MS);    // shorten WD timeout
    while (1)                  // and busy-loop so that WD causes
      ;                      //  a reset and app start.
  }
  putch(STK_INSYNC);
}

#if LED_START_FLASHES > 0
void flash_led(uint8_t count) {
  //LED_PIN |= _BV(LED);
  do {
    #if defined(__AVR_ATtiny261__)||defined(__AVR_ATtiny461__)||defined(__AVR_ATtiny861__) || defined(__AVR_ATtiny25__)||defined(__AVR_ATtiny45__)||defined(__AVR_ATtiny85__)
        TCNT1 = 0xFF&((uint8_t)(-(F_CPU/(8192L*16))));
        TIFR = _BV(TOV1);
        while(!(TIFR & _BV(TOV1)));
    #elif defined(__AVR_ATtiny43__)
        #error "LED flash for Tiny43 not yet supported"
    #else
        TCNT1 = (uint16_t)(-(F_CPU/(1024*16)));
        TIFR1 = _BV(TOV1);
        while(!(TIFR1 & _BV(TOV1)));
    #endif
    LED_PIN |= _BV(LED);
    watchdogReset();
  #ifndef SOFT_UART
    /*
     * While in theory, the STK500 initial commands would be buffered
     *  by the UART hardware, avrdude sends several attempts in rather
     *  quick succession, some of which will be lost and cause us to
     *  get out of sync.  So if we see any data; stop blinking.
     */
  #ifndef LIN_UART
    if (UART_SRA & _BV(RXC0))
  #else
    if (LINSIR & _BV(LRXOK))
  #endif
    break;
  #else
  // This doesn't seem to work?
  //    if ((UART_PIN & (1<<UART_RX_BIT)) == 0)
  //    break;  // detect start bit on soft uart too.
  #endif
  } while (--count);
}
#endif

// Watchdog functions. These are only safe with interrupts turned off.
void watchdogReset() {
  __asm__ __volatile__ (
    "wdr\n"
  );
}

void watchdogConfig(uint8_t x) {
#ifdef WDCE //does it have a Watchdog Change Enable?
 #ifdef WDTCSR
  WDTCSR = _BV(WDCE) | _BV(WDE);
 #else
  WDTCR= _BV(WDCE) | _BV(WDE);
 #endif
#else //then it must be one of those newfangled ones that use CCP
  CCP=0xD8; //so write this magic number to CCP
#endif

#ifdef WDTCSR
  WDTCSR = x;
#else
  WDTCR= x;
#endif
}


/*
 * void writebuffer(memtype, buffer, address, length)
 */
static inline void writebuffer(int8_t memtype, addr16_t mybuff,
                   addr16_t address, pagelen_t len)
{
    switch (memtype) {
    case 'E': // EEPROM
#if defined(SUPPORT_EEPROM) || defined(BIGBOOT)
        while(len--) {
        eeprom_write_byte((address.bptr++), *(mybuff.bptr++));
        }
#else
    /*
     * On systems where EEPROM write is not supported, just busy-loop
     * until the WDT expires, which will eventually cause an error on
     * host system (which is what it should do.)
     */
    while (1)
        ; // Error: wait for WDT
#endif
    break;
    default:  // FLASH
    /*
     * Default to writing to Flash program memory.  By making this
     * the default rather than checking for the correct code, we save
     * space on chips that don't support any other memory types.
     */
    {
        // Copy buffer into programming buffer
        uint16_t addrPtr = address.word;

        /*
         * Start the page erase and wait for it to finish.  There
         * used to be code to do this while receiving the data over
         * the serial link, but the performance improvement was slight,
         * and we needed the space back.
         */
#ifdef FOURPAGEERASE
        if ((address.bytes[0] & ((SPM_PAGESIZE<<2)-1))==0) {
#endif
        __boot_page_erase_short(address.word);
        boot_spm_busy_wait();
#ifdef FOURPAGEERASE
        }
#endif

        /*
         * Copy data from the buffer into the flash write buffer.
         */
        do {
        __boot_page_fill_short((uint16_t)(void*)addrPtr, *(mybuff.wptr++));
        addrPtr += 2;
        } while (len -= 2);

        /*
         * Actually Write the buffer to flash (and wait for it to finish.)
         */
        __boot_page_write_short(address.word);
        boot_spm_busy_wait();
#if defined(RWWSRE)
        // Re-enable read access to flash
        __boot_rww_enable_short();
#endif
    } // default block
    break;
    } // switch
}

static inline void read_mem(uint8_t memtype, addr16_t address, pagelen_t length)
{
    uint8_t ch;

    switch (memtype) {

#if defined(SUPPORT_EEPROM) || defined(BIGBOOT)
    case 'E': // EEPROM
    do {
        putch(eeprom_read_byte((address.bptr++)));
    } while (--length);
    break;
#endif
    default:
    do {
#ifdef VIRTUAL_BOOT_PARTITION
        // Undo vector patch in bottom page so verify passes
        if (address.word == rstVect0) ch = rstVect0_sav;
        else if (address.word == rstVect1) ch = rstVect1_sav;
        else if (address.word == saveVect0) ch = saveVect0_sav;
        else if (address.word == saveVect1) ch = saveVect1_sav;
        else ch = pgm_read_byte_near(address.bptr);
        address.bptr++;
#elif defined(RAMPZ)
        // Since RAMPZ should already be set, we need to use EPLM directly.
        // Also, we can use the autoincrement version of lpm to update "address"
        //      do putch(pgm_read_byte_near(address++));
        //      while (--length);
        // read a Flash and increment the address (may increment RAMPZ)
        __asm__ ("elpm %0,Z+\n" : "=r" (ch), "=z" (address.bptr): "1" (address));
#else
        // read a Flash byte and increment the address
        __asm__ ("lpm %0,Z+\n" : "=r" (ch), "=z" (address.bptr): "1" (address));
#endif
        putch(ch);
    } while (--length);
    break;
    } // switch
}


#ifndef APP_NOSPM

/*
 * Separate function for doing spm stuff
 * It's needed for application to do SPM, as SPM instruction works only
 * from bootloader.
 *
 * How it works:
 * - do SPM
 * - wait for SPM to complete
 * - if chip have RWW/NRWW sections it does additionally:
 *   - if command is WRITE or ERASE, AND data=0 then re-enable RWW section
 *
 * In short:
 * If you play erase-fill-write, just set data to 0 in ERASE and WRITE
 * If you are brave, you have your code just below bootloader in NRWW section
 *   you could do fill-erase-write sequence with data!=0 in ERASE and
 *   data=0 in WRITE
 */
static void do_spm(uint16_t address, uint8_t command, uint16_t data)  __attribute__ ((used));
static void do_spm(uint16_t address, uint8_t command, uint16_t data) {
    // Do spm stuff
    asm volatile (
    "    movw  r0, %3\n"
    "    __wr_spmcsr %0, %1\n"
    "    spm\n"
    "    clr  r1\n"
    :
    : "i" (_SFR_MEM_ADDR(__SPM_REG)),
        "r" ((uint8_t)command),
        "z" ((uint16_t)address),
        "r" ((uint16_t)data)
    : "r0"
    );

    // wait for spm to complete
    //   it doesn't have much sense for __BOOT_PAGE_FILL,
    //   but it doesn't hurt and saves some bytes on 'if'
    boot_spm_busy_wait();
#if defined(RWWSRE)
    // this 'if' condition should be: (command == __BOOT_PAGE_WRITE || command == __BOOT_PAGE_ERASE)...
    // but it's tweaked a little assuming that in every command we are interested in here, there
    // must be also SELFPRGEN set. If we skip checking this bit, we save here 4B
    if ((command & (_BV(PGWRT)|_BV(PGERS))) && (data == 0) ) {
      // Re-enable read access to flash
      __boot_rww_enable_short();
    }
#endif
}
#endif



#ifdef BIGBOOT
/*
 * Optiboot is designed to fit in 512 bytes, with a minimum feature set.
 * Some chips have a minimum bootloader size of 1024 bytes, and sometimes
 * it is desirable to add extra features even though 512bytes is exceedded.
 * In that case, the BIGBOOT can be used.
 * Our extra features so far don't come close to filling 1k, so we can
 * add extra "frivolous" data to the image.   In particular, we can add
 * information about how Optiboot was built (which options were selected,
 * what version, all in human-readable form (and extractable from the
 * binary with avr-strings.)
 *
 * This can always be removed or trimmed if more actual program space
 * is needed in the future.  Currently the data occupies about 160 bytes,
 */
#define xstr(s) str(s)
#define str(s) #s
#define OPT2FLASH(o) char f##o[] = #o "=" xstr(o)


#ifdef LED_START_FLASHES
OPT2FLASH(LED_START_FLASHES);
#endif
#ifdef LED_DATA_FLASH
OPT2FLASH(LED_DATA_FLASH);
#endif
#ifdef LED_START_ON
OPT2FLASH(LED_START_ON);
#endif
#ifdef LED_NAME
char f_LED[] = "LED=" LED_NAME;
#endif

#ifdef SUPPORT_EEPROM
OPT2FLASH(SUPPORT_EEPROM);
#endif
#ifdef BAUD_RATE
OPT2FLASH(BAUD_RATE);
#endif
#ifdef SOFT_UART
OPT2FLASH(SOFT_UART);
#endif
#ifdef UART
OPT2FLASH(UART);
#endif

char f_date[] = "Built:" __DATE__ ":" __TIME__;
#ifdef BIGBOOT
OPT2FLASH(BIGBOOT);
#endif
#ifdef VIRTUAL_BOOT_PARTITION
char f_boot[] = "Virtual_Boot_Partition";
#endif
OPT2FLASH(F_CPU);
char f_device[] = "Device=" xstr(__AVR_DEVICE_NAME__);
#ifdef OPTIBOOT_CUSTOMVER
OPT2FLASH(OPTIBOOT_CUSTOMVER);
#endif
char f_version[] = "Version=" xstr(OPTIBOOT_MAJVER) "." xstr(OPTIBOOT_MINVER);

#endif
